KR101827459B1 - Field service device and method for facilitating a processing system replacement in a vibratory flowmeter - Google Patents

Abstract

An on-site maintenance device 280 is provided to facilitate replacement of the processing system in the vibratory flow meter. The field service equipment 280 includes a field service unit processor 282 and a replacement-before-operation-derived value 252a, a replacement-after-operation-derived value 252b configured to interface with one or more vibratory flow meter processing systems, And a storage system 285 configured to store one or more adjustment factors 266. The field service device processor 282 obtains the pre-replacement operation-derived values 252a, obtains the post-replacement operation-derived values 252b after the old processing system is replaced with the replacement processing system, Generate one or more adjustment factors 266 as a ratio of one or more replacement-pre-operation-derived values 252a to the replacement-after-operation-derived values 252b, Lt; / RTI >

Description

FIELD SERVICE DEVICE AND METHOD FOR FACILITATING A PROCESSING SYSTEM REPLACEMENT IN A VIBRATORY FLOWMETER BACKGROUND OF THE INVENTION Field of the Invention [0001]

Field of the Invention The present invention relates to field service devices and methods for vibratory flow meters, and more particularly to methods for facilitating replacement of processing systems in field maintenance equipment and vibratory flow meters.

Vibrating conduit sensors, such as Coriolis mass flow meters and vibration densitometers, typically operate by sensing the motion of a vibrating conduit comprising a flow material. Properties associated with the material in the conduit, such as flow, concentration, etc., can be determined by processing the measurement signals received from the motion transducers associated with the conduit. The vibration modes of a vibrating material-rechargeable system are generally influenced by the combined mass, strength, and damping characteristics of the materials contained within the conduits and conduits involved.

A typical Coriolis mass flow meter includes one or more conduits that are connected inline to a pipeline or other delivery system and transport materials in the system, e.g., fluids, slurries, emulsions, and the like. Each conduit can be seen to have a set of natural vibration modes including, for example, simple bending, torsion, radial, and coupling modes. In a typical Coriolis mass flow measurement application, when material flows through a conduit, the conduit is excited in one or more vibration modes and the motion of the conduit is measured at points spaced along the conduit. The exciter is typically provided by an electromechanical device, such as an actuator, for example a voice coil-type actuator, that perturbs the conduit in a periodic fashion. The mass flow rate can be determined by measuring the time lag or phase differences between movements in transducer locations. Two such transducers (or pick-off sensors) are typically employed to measure the vibrational response of flow conduits or conduits, and are typically located at upstream and downstream positions of the actuator. The two pick-off sensors are connected to the electronics. The electronics receive signals from the two pick-off sensors and process the signals to induce a particularly mass flow measurement. Thus, vibratory flow meters, including Coriolis mass flow meters and densitometers, employ one or more flow tubes that are vibrated to measure fluids.

During operation, the instrumentation electronics of the vibrating flow meter can acquire unique and useful data. The data may include configuration data constituting a vibratory flow meter. The data may include calibration data to calibrate the measurements produced by the vibratory flow meter. The data may include meter verification data to confirm proper operation of the vibratory flow meter.

This data is important for proper operation of the flowmeter. Such data may include data reflecting the current operating state of the vibratory flow meter, where the data may include information about changes to the vibratory flow meter over time. Changes in vibration characteristics may be due to, for example, use, corrosion, erosion and / or other factors. These changes to the flow meters can be captured in the data.

Problems arise when the vibrating flow meter's processing system needs to be replaced. The processing system may even be required to be replaced even when only a partial failure has occurred. It should be understood that the failure may not necessarily affect the memory storing such data.

Replacement of the processing system causes difficulties. Replacement of the processing system may be accomplished by replacing the post-replacement operational data, which is generated after installation of the replacement processing system and adjusted differently by pre-replacement operational data by gain differences through the electronic device resulting in post-replacement operational data. Comparing the new operating data to the replacement-before operating data may inappropriately indicate failures in the instrument by this adjustment difference. As a result, the switching of the processing system can be problematic and difficult.

Currently, when an enhanced core processor fails, the factory baseline must be reset by a field mechanic. The field mechanic must operate the same algorithm as that performed in the factory to reset the new factory standard. This process can be problematic due to customer timing, personnel mobility, and so on. The root cause for a requirement to reset a standard with a new core is due to the fact that the electronics are changed by component tolerances. Component tolerances can be considerably larger than the required precision of gauge verification results.

In one aspect of the present invention, a field service device for facilitating replacement of a processing system in a vibrating flow meter includes:

An on-site maintenance device processor configured to interface with one or more vibratory flow meter processing systems; And

To store the pre-replacement operation-induced values, the post-replacement operation-induced values, and one or more scaling factors coupled to the field service unit processor Gt; a < / RTI > storage system,

The field service device processor obtains the replacement-pre-operation-induced values of the vibratory flow meter and acquires the replacement-after-operation-derived values from the vibration flow meter after the old processing system is replaced with the replacement processing system ), Generating one or more adjustment factors as a ratio of one or more alternate-to-pretreatment-derived values to one or more of the replacement-after-operation-derived values, and determining one or more of the replacement processing system or monitoring computer , And the one or more adjustment factors may be used to process the manipulation-derived values.

Preferably, the method further comprises holding one or more adjustment factors in the storage system of the field service equipment.

Preferably, the storage system further comprises a data upload routine for uploading the replacement-before manipulation-derived values from the old processing system, an adjustment factor routine for generating one or more adjustment factors, and one or more adjustment factors for replacement processing And further stores a data download routine for downloading to the system.

Advantageously, obtaining the pre-change operation-derived values includes obtaining the pre-change operation-derived values from the old processing system.

Preferably, obtaining the pre-change operation-derived values comprises obtaining the pre-change operation-derived values from the manufacturer's facility.

Preferably, one or more adjustment factors are used to adjust the post-manipulation-induced values.

Preferably, one or more adjustment factors are used to adjust the inter-pre-operation-induced values.

Preferably, one or more adjustment factors are used to adjust the vibratory flow meter measurements.

Preferably, the old processing system is replaced in the vibrating flow meter by the replacement processing system prior to adjustment.

Preferably, the old processing system is replaced in the oscillating flow meter by the replacement processing system after adjustment.

In one aspect of the invention, a method of replacing a processing system for a vibratory flow meter comprises:

Acquiring replacement-pre-operation-induced values of the vibratory flow meter;

Replacing the old processing system of the vibrating flow meter with a replacement processing system;

Operating the vibratory flow meter using the replacement processing system to generate replacement-after-operation-derived values;

Generating one or more adjustment factors as a ratio of one or more replacement-previous manipulation-induced values to one or more of the post-manipulation-derived values; And

And using the one or more adjustment factors to process the manipulation-induced values.

Advantageously, the step of acquiring the pre-change operation-derived values comprises obtaining the pre-change operation-derived values from the old processing system.

Preferably, the step of acquiring the interchange-pre-operation-derived values comprises acquiring the interchange-pre-operation-derived values from the manufacturer's facility.

Preferably, one or more adjustment factors are used to adjust the post-manipulation-induced values.

Preferably, one or more adjustment factors are used to adjust the inter-pre-operation-induced values.

Preferably, one or more adjustment factors are used to adjust the vibratory flow meter measurements.

Preferably, the old processing system is replaced with a replacement processing system in the vibratory flow meter prior to adjustment.

Advantageously, said old processing system is replaced with said replacement processing system in said vibratory flow meter after adjustment.

Like numbers refer to like elements throughout. The drawings are not necessarily drawn to scale.
1 shows a vibration flow meter according to the present invention.
Figure 2 shows a measurement electronics of a vibratory flow meter according to an embodiment of the invention.
Figure 3 shows a field service device used to replace an old processing system of a metrology electronics of a vibratory flow meter according to an embodiment of the present invention.
4 is a flowchart of a method for replacing a processing system for a vibrating flow meter according to an embodiment of the present invention.

1 to 4 and the following description illustrate specific examples for teaching those skilled in the art how to make and use the best mode of the present invention. In order to teach the principles of the present invention, certain prior art aspects have been simplified or omitted. Those skilled in the art will recognize variations from these examples that are within the scope of the present invention. Those skilled in the art will appreciate that the features described below can be combined in various ways to form many variations of the invention. As a result, the present invention is not limited to the specific examples described below, but is limited only to the equivalents of the claims and the claims.

1 shows a vibration flow meter 5 according to the present invention. The vibratory flow meter 5 includes a meter assembly 10 and a metrology electronics 20. The metrology electronics 20 are connected to the metering assembly 10 via the leads 100 and are connected to the metering assembly 10 via the leads 100 to determine the concentration, mass flow, volumetric flow, total mass flow, temperature, And is configured to provide one or more measurements. It should be apparent to those skilled in the art that the vibratory flow meter 5 may include any type of vibratory flow meter, regardless of the actuators, pick-off sensors, number of flow conduits, or mode of operation of the vibrations. In some embodiments, the vibratory flow meter 5 may comprise a Coriolis mass flow meter. It should also be appreciated that the vibratory flow meter 5 may alternatively comprise a vibrating densitometer.

The flow meter assembly 10 includes a pair of flanges 101a and 101b, manifolds 102a and 102b, a driver 104, pick-off sensors 105a and 105b, and flow conduits 103A and 103B. . The driver 104 and the pick-off sensors 105a and 105b are connected to the flow conduits 103A and 103B.

Flanges 101a and 101b are attached to manifolds 102a and 102b. The manifolds 102a and 102b may be attached to opposite ends of the spacer 106 in certain embodiments. The spacers 106 maintain spacing between the manifolds 102a and 102b to prevent pipeline forces from being transferred to the flow conduits 103A and 103B. When the flow meter assembly 10 is inserted into a pipeline (not shown) that carries the flow fluid being measured, the flow fluid enters the flow meter assembly 10 through the flange 101a and the total amount of flow fluid flows through the flow conduit 103A and 103B and into the outlet manifold 102b through the flow conduits 103A and 103B where the flow fluid passes through the flange 101b through the inlet manifold 102a, Assembly 10.

The flow fluid may comprise a liquid. The flow fluid may comprise gas. The flow fluid may comprise a polyphase fluid such as a liquid comprising entrained gases and / or entrained solids.

The flow fluids 103A and 103B are selected such that the inlet manifolds 102a and 102b have elastic modules for each of the selected and substantially identical mass distributions, moments of inertia, and bending axis (Wa - Wa and Wb - Wb) And is appropriately mounted on the outlet manifold 102b. The flow conduits 103A and 103B extend outwardly from the manifolds 102a and 102b in an essentially parallel manner.

The flow conduits 103A and 103B are driven by the driver 104 in opposite directions about respective bending axes Wa and Wb and are referred to as the first phase difference bending mode of the oscillating flow meter 5. Actuator 104 may include one of a number of known arrangements such as a magnet mounted on flow conduit 103A and an opposing coil mounted on flow conduit 103B. The alternating current passes through the opposing coils causing an oscillation of both conduits. A suitable drive signal is applied to the driver 104 by the metrology electronics 20 via a lead 110. Other driver arrangements are contemplated and are within the scope of the description and claims.

The metrology electronics 20 receive the sensor signals on leads 111a and 111b, respectively. The metrology electronics 20 generate drive signals on the leads 110 that cause the drivers 104 to oscillate the flow conduits 103A and 103B. Other sensor devices are contemplated and are within the scope of the description and claims.

The meter electronics 20 processes the left and right velocity signals from the pick-off sensors 105a and 105b, in particular to calculate the flow rate. The communication path 26 provides input and output means that allow the metering electronics 20 to interface with the operator or other electronic systems. The description of Figure 1 is provided only as an example of operation of a Coriolis flowmeter and is not intended to limit the teachings of the present invention.

The metrology electronics 20 are configured to vibrate the flow tubes 103A and 103B in one embodiment. The vibration is performed by the driver 104. The metrology electronics 20 additionally receive the resulting vibration signals from the pick-off sensors 105a and 105b. The vibration signals include the vibration responses of the flow tubes 103A and 103B. The metrology electronics 20 process the vibrational responses and determine the response frequency and / or phase difference. The metrology electronics 20 process one or more vibration responses and determine one or more flow measurements, including the concentration and / or mass flow rate of the flow fluid. Other vibration response characteristics and / or flow measurements are contemplated and are within the scope of the detailed description and claims.

In one embodiment, the flow tubes 103A and 103B include substantially U-shaped flow tubes, as shown. Alternatively, in other embodiments, the flow tubes may comprise substantially straight flow tubes or may comprise one or more flow tubes of curved shapes other than U-shaped flow tubes. Additional meter geometries and / or configurations may be used and are within the scope of the description and claims.

Figure 2 shows a measurement electronics 20 of a vibratory flow meter 5 according to an embodiment of the invention. The metrology electronics 20 may include an interface 201 and a processing system 203. The meter electronics 20 receives one or more sensor signals 221 from the meter assembly 10, such as pick-off sensor signals from the pick-off sensors 105a and 105b. The metrology electronics 20 process the first and second sensor signals to obtain flow properties 228 of the flowing material flowing through the metrology assembly 10. For example, the metrology electronics 20 may include one or more of, for example, phase difference, frequency, time difference [Delta] t, concentration, mass flow rate, and volume flow rate from sensor signals 221 The flow characteristics 228 can be determined. In addition, other flow characteristics 228 may be determined in accordance with the present invention.

The interface 201 receives sensor signals from one of the speed sensors 170L and 170R via the leads 100 of FIG. The interface 201 may perform any necessary or desired signal conditioning, such as formatting, amplifying, buffering, etc., in any manner. Alternatively, some or all of the signal conditioning may be performed in the processing system 203.

The interface 201 may also enable communications between the metering electronics 20 and external devices, such as via communications path 26, for example. The interface 201 may be implemented in any of electronic, optical, or wireless communication.

The interface 201 includes, in one embodiment, a digitizer (not shown), wherein the sensor signal includes an analog sensor signal. The digitizer samples and digitizes analog sensor signals and generates digital sensor signals. The interface / digitizer can also perform any desired decimation, where the digital sensor signal is decimated to reduce the amount of signal processing required and reduce processing time.

The processing system 203 guides the operations of the metrology electronics 20 and processes flow measurements from the meter assembly 10. The processing system 203 executes one or more processing routines to thereby process flow measurements to produce one or more flow characteristics.

The processing system 203 may comprise a general purpose computer, a microprocessing system, a logic circuit, or some other general purpose or custom processing device. The processing system 203 may be distributed among a plurality of processing devices. The processing system 203 may include any type of integrated or stand alone electronic storage medium, such as the storage system 204. [

In the illustrated embodiment, the processing system 203 determines flow characteristics from one or more sensor signals 221. The processing system 203 may determine at least the frequency and phase difference of one or more sensor signals 221 and may determine the mass flow rate and concentration from, for example, the phase difference and frequency.

The storage system 204 may store flow meter parameters and data, software routines, constants, and variables. In one embodiment, the storage system 204 stores routines that are executed by the processing system 203. In one embodiment, the storage system 204 stores an operational routine 210. When executed by the processing system 203, the operational routine 210 may operate the vibratory flow meter 5, which vibrates the flow assembly 10 and receives one or more subsequent sensor signals 221, And generating one or more flow characteristics (228) from the one or more sensor signals (221). The manipulation routine 210 may also perform other manipulations including, for example, communication manipulations and gauge confirmation manipulations. Other instrument tasks are contemplated and are within the scope of the description and claims.

In one embodiment, the storage system 204 stores the variables used to operate the Coriolis flowmeter 5. The storage system 204 may store one or more sensor signals 221 received from the pick-off sensors 105a and 105b. The storage system 204 may store one or more flow characteristics 228 derived from one or more sensor signals 221. In addition, the storage system 204 may store a factory baseline data set 263 and store the operation-derived values 252.

The factory reference data set 263 may include a plurality of reference values. The factory reference data set 263 may contain data to be programmed into the vibratory flow meter 5 at the factory or may be programmed into the vibratory flow meter after delivery and installation of the vibratory flow meter 5.

The factory reference data set 263 may include the required configuration values to configure the vibratory flow meter 5. The configuration values may include, for example, information such as one or more flow material concentrations, one or more target oscillation amplitudes, and one or more target oscillation frequencies. Other configuration values are contemplated and are within the scope of the description and claims.

The factory reference data set 263 may include calibration values required to provide accurate and reliable flow measurement values from raw measurement data. The calibration values may include, for example, a flow correction factor (FCF) characterizing the strength and geometry of the meter. Calibration values are flow tubes zero (zero), including the time delay (△ t) between (103A and 103B) flows the pickoff sensors (105a and 105b) in the absence with the-flow time delay correction value (△ t ₀₎ . ≪ / RTI > Other calibration values are contemplated and are within the scope of the detailed description and claims.

The factory reference data set 263 may contain confirmation values used to confirm the operation of the vibratory flow meter 5. Confirmation values may include, for example, concentration confirmation values. Other identification values are contemplated and are within the scope of the description and claims.

The operation-induced values 252 may include values derived during operation of the vibratory flow meter 5. The operation-induced values 252 may include factory reference values of the factory-based data set 263 that have been changed during operation of the vibratory flow meter 5.

Figure 3 illustrates a field service device 280 for facilitating the replacement of the processing system in the vibratory flow meter 5 according to one embodiment of the present invention. Field service device 280 includes a processor 282 configured to interface with one or more vibratory flow meter processing systems and a storage system 285 coupled to the processor 282. The field service equipment 280 may be used to configure the replacement processing system 203b. The field service device 280 may be used to configure the replacement processing system 203b to generate non-disjoint operation-derived values from the operation-derived values generated by the old processing system 203a.

In the figure, the metrology electronics 20 includes a "sphere" metrology electronics 20, including an old processing system 203a on the left side. The old processing system 203a may store the replace-before-operation-derived values 252a. The pre-operation-induced values 252a may include values derived during operation of the vibratory flow meter 5, as discussed above. The replacement-before manipulation-derived values 252a may include factory reference values that have changed during manipulation of the oscillating flow meter 5, as discussed above (the old processing system 203a may include factory reference data set 263) Can be saved). The factory reference data set 263 may contain factory reference data that is programmed into the vibratory flow meter 5, as discussed above. The factory reference data set 263 may include configuration, calibration, and verification values, as discussed above.

The metrology electronics 20 include metrology electronics 20 on the right side after replacement of the old processing system 203a with the replacement processing system 203b. The replacement processing system 203b may generate and store the replacement-after-operation-derived values 252b. The replacement-after-operation-derived values 252b may include adjusted operation-derived values, as discussed below in some embodiments.

The field service device 280 may include a communication interface (not shown) coupled to the processor 282 and configured to communicate with the meter electronics 20. The field service device 280 may communicate with the metering electronics 20 using any suitable communication link including wired connection, wireless, or electrical, magnetic, radio, acoustic, or optical communication systems.

The field service equipment 280 further includes a storage system 285 coupled to the processor 282. The storage system 285 is configured to store pre-deployment operation-derived values 252a, post-deployment operation-derived values 252b, and one or more adjustment factors 266. [ Other values or information are contemplated and are within the scope of the description and claims.

The storage system 285 may store routines to be executed by the processor 282. The storage system 285 may store a data upload routine 246, a data download routine 247, and an adjustment factor routine 249. Other routines are contemplated and are within the scope of the description and claims.

The data upload routine 246 may be used by the processor 282 to upload information from the metrology electronics 20 to the storage system 285 of the field service equipment 280. The data upload routine 246 may be used to upload manipulation-derived values 252 of the old processing system 203. The data upload routine 246 may be used to upload the replacement-before manipulation-derived values 252a from the old processing system 203. [ The data upload routine 246 may be used to upload the replacement-post-operation-derived value 252b from the replacement processing system 203b. Alternatively, or in addition, the data upload routine 246 may upload data from other sources, such as a monitoring or data accumulation computer in communication with the vibratory flow meter 5.

The data download routine 247 may be used by the processor 282 to download information from the storage system 285 of the field service equipment 280 to the metering electronics 20. The data download routine 247 may be used, for example, to download one or more adjustment factors 266 from the storage system 285 of the field service equipment 280 to the replacement processing system 203b. Alternatively, or in addition, the data download routine 247 may download one or more adjustment factors 266 to other devices, such as a monitoring or data accumulation computer, that communicates with the vibratory flow meter 5.

The adjustment routine 249 may be used by the processor 282 to generate one or more adjustment factors 266. [ The adjustment routine 249 may generate one or more adjustment factors 266 from the replacement-before-operation-derived values 252a and the replacement-after-operation-derived values 252b. The adjustment routine 249 may generate one or more adjustment factors 266 as a percentage of the replacement-before-operation-derived values 252a for the replacement-after-operation-derived values 252b. The adjustment routine 249 may include one or more adjustment factors 266 as a ratio of one or more replacement-to-previous-operation-derived values 252a to one or more of the replacement-after-operation-derived values 252b Where a number of adjustment factors 266 can be created. A number of such adjustment factors 266 may be required if different items in the manipulation-induced values, such as when amplification factors are applied, may be required to be individually or differently adjusted.

One or more adjustment factors 266 may be used by the vibratory flow meter 5 to adjust vibratory flow meter measurements. One or more adjustment factors 266 may be used to adjust the instrument configuration values. One or more adjustment factors 266 may be used to adjust the instrument calibration values. One or more adjustment factors 266 may be used to adjust gauge confirmations. Alternatively, or in addition, one or more adjustment factors 266 may be used by the monitoring or data accumulating computer in communication with the oscillating flow meter 5.

The processor 282 acquires the replacement-before-operation-derived values 252a of the vibratory flow meter 5 and updates the replacement processing system 203b from the replacement processing system 203b after the old processing system 203a has been replaced with the replacement processing system 203b Derived values 252b for one or more of the post-manipulation-derived values 252b for one or more of the post-manipulation-derived values 252b, Such as a monitoring or data accumulation computer that communicates with the alternate processing system 203b and / or the vibratory flow meter 5, and / or other appropriate computer And downloaded to the computers. One or more adjustment factors 266 may be used by the replacement processing system 203b and / or other computers to adjust the manipulation-derived values 252. [ Thus, the replacement operating system 203b can operate substantially the same as the old processing system 203a.

The field service device 280 may be used to diagnose and / or repair the meter electronics 20 of the vibratory flow meter 5. The field service equipment 280 may be configured to detect problems with the processing system 203 of the vibratory flow meter 5, including detecting or determining whether the processing system 203 needs to be replaced.

4 is a flow diagram 400 of a method for replacing a processing system for a vibratory flow meter 5 in accordance with one embodiment of the present invention. In step 401, the replacement-before operation-derived values 252a are uploaded to the field service equipment 280. [ The field maintenance apparatus 280 may be operated by a technician or a repairman.

The replacement-previous manipulation-derived values 252a may be uploaded from the old processing system 203a. Alternatively, the uploading may include uploading the interchange-pre-operation-derived values 252a from the external device to the vibratory flow meter 5. The external device may include a local computer device that communicates with one or more flow meters and receives and collects data from the one or more flow meters. The external device may include a factory server, database, or other factory storage. The replacement-before manipulation-induced values 252a may be stored outside the vibratory flow meter 5, for example during a data backup procedure. Consequently, the replacement-before-operation-derived values 252a may even be available even when the old processing system 203a is completely non-functional.

The replacement-before manipulation-derived values 252a include values generated during manipulation of the oscillation flow meter 5 by the old processing system 203a. The uploading of the replacement-prior manipulation-derived values 252a may be performed prior to the replacement of the old processing system 203a.

The replacement-before manipulation-induced values 252a may comprise the programmed values into the oscillating flow meter 5. [ The configuration values may not be changed or may be modified during operation by the vibratory flow meter (5).

The interchange-pretreatment values 252a may include calibration values, such as, for example, tube strength values, and residual tube flexibility values. The calibration values may not be changed or may be modified during operation by the vibratory flow meter (5). It is to be understood that other calibration values are contemplated and are within the scope of the following description and claims.

The replacement-prior manipulation-derived values 252a may include a portion of the factory reference data set 263 stored in the oscillating flow meter 5 and changed by on-site manipulation. Changes to the factory reference data set 263 may occur over time, during on-site operation of the vibration parameter 5.

Variations over time for the pre-replacement operation-induced values 252a may be specific to the particular vibratory flow meter 5. Consequently, it may be desirable that the replacement-before-operation-derived values 252a are performed from the old processing system 203a into the replacement processing system 203b. The replacement-before-operation-derived values 252a may enable the replacement processing system 203b to be operated substantially the same as the old processing system 203a.

In step 402, the old processing system 203a of the vibratory flow meter 5 is replaced with a replacement processing system 203b. The replacement step may include replacing the processor or processors within the metrology electronics 20. [ The replacement step may include replacing one or more circuit boards of the metrology electronics 20. The alternate step may include replacing chips, sub-boards, or circuits or components of the metrology electronics 20.

At step 403, the vibratory flow meter 5 is operated by the installed replacement processing system 203b, at which time the replacement-after-operation-derived values 252b are collected by the replacement processing system 203b. The replacement-after-operation-derived values 252b are preferably acquired by the original meter assembly 10. Replacement-post-manipulation-derived values 252b may be obtained using a new gain value or values by use of the replacement processing system 203b. The replacement-after-operation-derived values 252b may be discontinuous from the replacement-before-operation-derived values 252a.

At step 404, one or more adjustment factors 266 are generated. One or more adjustment factors 266 are generated from the comparison of the replacement-before-operation-derived values 252a for the replacement-after-operation-derived values 252b. One or more adjustment factors 266 may be generated for the replacement-post-operation-derived values 252a (formerly processing system (not shown) for replacement-after-operation-derived values 252b 203a), i. E., The pre-swap values / post-swap values.

In step 405, one or more adjustment factors 266 are used to process the manipulation-derived values. One or more adjustment factors may be downloaded to the vibratory flow meter 5 and / or downloaded to one or more appropriate monitoring or data accumulating computers in communication with the vibratory flow meter 5. [ Consequently, the processing may be performed in the field service unit 280, or may be performed in other devices, such as a vibrating flow meter 5 external device, and / or removed from the vibrating flow meter.

In certain embodiments, one or more adjustment factors 266 may be downloaded to the replacement processing system 203b and used by the replacement processing system. The downloaded one or more adjustment factors 266 may be stored in any suitable storage unit in the replacement processing system 203b, including, for example, any type of non-volatile memory. One or more adjustment factors 266 may then be used by the replacement processing system 203b. One or more adjustment factors 266 may be used to adjust the post-replace manipulated-induction values subsequently generated by the oscillating flow meter 5. As a result of the adjustment, the replacement-after-operation-derived values may not show a change or discontinuity when compared with the replacement-before-operation-induced values.

Alternatively, one or more adjustment factors 266 may be used to adjust the replacement-before-operation-induced values instead of the adjustment of subsequent operation-induced values. This may require turning over the proportions or ratios used to either steer one or more adjustment factors 266 or to generate one or more adjustment factors 266. [

One or more adjustment factors 266 may be used to adjust vibratory flow meter measurements. One or more adjustment factors 266 may be used to adjust gauge confirmations. One or more adjustment factors 266 may be used to adjust the instrument calibration values. One or more adjustment factors 266 may be used to adjust the instrument configuration values.

The manipulation-induced values may include user-usable data that preferably is retained in the oscillating flow meter. The manipulation-induced values may be user-accessible through instrument-coupled devices, including diagnostic tools, and over a communication link. The manipulation-derived values may include data collected for possible future diagnostic use. Thus, the manipulation-derived values may comprise externally-available instrument measurement data and / or internal data, including manipulation data and manipulation states. Furthermore, the manipulation-derived values may include mode analysis data by modal analysis fitting the data measured with the parametric model and analyzing the results.

The manipulation-induced values may include amplifier calibration data. The amplifier calibration data may include amplifier calibration coefficients that can be used to verify that the drive current amplifier of the vibrating flow meter is not essentially changed from the factory values. The flow meter can measure frequency response functions (FRFs) in one or more vibration test tones. The acquired FRFs can be compared to the stored amplifier calibration coefficients, where the deviation (or amount of deviation) can be used to deduce a change or deterioration within the vibrating flow meter. The measured FRFs, and the amount of deviation, may be stored as diagnostic or confirmation data.

The manipulation-derived values may include filtering data. The filtering data may include stored filtering information such as, for example, filter response times, orders of filters, number and spacing of filter taps, decimation information, and stopband information. have.

The manipulation-induced values may include flow tube / flow meter residual flexibility data. Residual flexibility data can be calculated from the FRFs, where the residual flexibility matrix is derived from the residual matrix and residual processing of the poles. Residual flexibility can result from mass unbalance or other structural anomalies in flow tubes or flow meter structures. Residual flexibility can be tracked over time, and any changes to the residual flexibility are used as a diagnosis to detect structural changes to the vibratory flow meter.

The manipulation-induced values may include intensity indeterminate data. Strength uncertainty data may include statistical data on changes in strength from factory standards. The intensity uncertainty data can characterize the intensity values versus the operating frequency of the flow meter.

The field service apparatus and method according to the present invention may be employed according to any of the embodiments to provide several advantages, if desired. Field service equipment and methods can be employed to facilitate switching of the processing system in the vibratory flow meter. The field service apparatus and method may be employed to facilitate replacement of the processing system in the vibratory flow meter wherein the replacement-after-operation-derived values are not different from the replacement-before operation-induced values, .

The detailed description of the embodiments is not intended to be a complete description of all embodiments considered by the inventors to be within the scope of the present invention. Indeed, those skilled in the art will recognize that certain elements of the embodiments described above may be variously combined or eliminated to make additional embodiments, and such additional embodiments are within the scope and teachings of the invention. It will also be apparent to those skilled in the art that the embodiments described above may be combined in whole or in part to create additional embodiments within the scope and teachings of the present invention. Accordingly, the scope of the present invention should be determined from the following claims.

Claims (18)

A field service device (280) for facilitating replacement of a processing system in a vibrating flow meter,
A field service device processor (282) configured to interface with one or more of the vibratory flow meter processing systems; And
Is coupled to the field service unit processor 282 and includes pre-replacement operation-derived values 252a, post-replacement operation-induced values 252b, and one or two And a storage system (285) configured to store scaling factors (266)
The field service device processor 282 obtains the replacement-pre-operation-derived values 252a of the vibratory flow meter and provides a replacement-pre-operation-derived value 252a from the vibration flow meter after the old processing system is replaced with the replacement processing system. Derived values 252b as a ratio of one or more replacement-before manipulation-derived values 252a to one or more of the post-manipulation-derived values 252b, Generating adjustment factors 266 and downloading the one or more adjustment factors 266 to one or more of the replacement processing system 203a or the monitoring computer, 266 may be used to process operation-induced values 252,
On-site maintenance to facilitate replacement of the processing system in the vibrating flow meter.
[Claim 2 is abandoned upon payment of the registration fee.] The method according to claim 1,
Further comprising holding one or more adjustment factors (266) in a storage system (285) of the field service equipment (280)
On-site maintenance to facilitate replacement of the processing system in the vibrating flow meter.
The method according to claim 1,
The storage system 285 may include a data upload routine 246 for uploading the replacement-before manipulation-derived values 252a from the old processing system, an adjustment parameter for generating the one or more adjustment factors 266, Routine 249 and a data download routine 247 for downloading the one or more adjustment factors 266 to the replacement processing system 203a.
On-site maintenance to facilitate replacement of the processing system in the vibrating flow meter.
[Claim 4 is abandoned upon payment of the registration fee.] The method according to claim 1,
Wherein the obtaining of the replace-before-operation-derived values comprises obtaining the replace-before-operation-derived value from the old processing system.
On-site maintenance to facilitate replacement of the processing system in the vibrating flow meter.
[Claim 5 is abandoned upon payment of registration fee.] The method according to claim 1,
Obtaining the replacement-before-operation-derived values comprises obtaining the replacement-before-operation-derived values from the manufacturer's facility.
On-site maintenance to facilitate replacement of the processing system in the vibrating flow meter.
The method according to claim 1,
The one or more adjustment factors 266 are used to adjust the replacement-after-
On-site maintenance to facilitate replacement of the processing system in the vibrating flow meter.
The method according to claim 1,
The one or more adjustment factors (266) are used to adjust the inter-pre-manipulation-induced values,
On-site maintenance to facilitate replacement of the processing system in the vibrating flow meter.
The method according to claim 1,
The one or more adjustment factors 266 are used to adjust vibratory flow meter measurements,
On-site maintenance to facilitate replacement of the processing system in the vibrating flow meter.
[Claim 9 is abandoned upon payment of registration fee.] The method according to claim 1,
Wherein the old processing system is replaced in the vibratory flow meter by the replacement processing system prior to the adjustment,
On-site maintenance to facilitate replacement of the processing system in the vibrating flow meter.
[Claim 10 is abandoned upon payment of the registration fee.] The method according to claim 1,
Wherein the old processing system is replaced in the vibratory flow meter by the replacement processing system after the adjustment,
On-site maintenance to facilitate replacement of the processing system in the vibrating flow meter.
A method of replacing a processing system for a vibrating flow meter,
Acquiring replacement-pre-operation-induced values of the vibratory flow meter;
Replacing the old processing system of the vibratory flow meter with a replacement processing system;
Operating the vibratory flow meter using the replacement processing system to generate replacement-after-operation-derived values;
Generating one or more adjustment factors as a ratio of one or more replacement-pre-manipulation-induced values to one or more of the post-manipulation-derived values; And
Using the one or more adjustment factors to process the manipulation-induced values,
How to replace a processing system for a vibrating flow meter.
12. The method of claim 11,
Wherein the step of acquiring the replacement-before manipulation-derived values comprises obtaining the replacement-before manipulation-derived values from the old processing system.
How to replace a processing system for a vibrating flow meter.
[13] has been abandoned due to the registration fee. 12. The method of claim 11,
Wherein the step of acquiring the pre-replacement operation-derived values comprises obtaining the pre-replacement operation-derived values from the manufacturer '
How to replace a processing system for a vibrating flow meter.
12. The method of claim 11,
Wherein the one or more adjustment factors are used to adjust the post-
How to replace a processing system for a vibrating flow meter.
12. The method of claim 11,
Wherein the one or more adjustment factors are used to adjust the alternate-
How to replace a processing system for a vibrating flow meter.
12. The method of claim 11,
Said one or more adjustment factors being used to adjust vibratory flow meter measurements,
How to replace a processing system for a vibrating flow meter.
[Claim 17 is abandoned upon payment of registration fee.] 12. The method of claim 11,
Wherein the old processing system is replaced in the vibratory flow meter by the replacement processing system prior to the adjustment,
How to replace a processing system for a vibrating flow meter.
[Claim 18 is abandoned upon payment of registration fee.] 12. The method of claim 11,
Wherein the old processing system is replaced in the vibratory flow meter by the replacement processing system after the adjustment,
How to replace a processing system for a vibrating flow meter.

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